Radiology Physics & Imaging Technology
Radiology Physics is the backbone of safe, high-quality imaging. This comprehensive module is designed to take radiology residents from first-principle physics to advanced modality-specific applications, ensuring conceptual clarity, exam readiness, and real-world clinical confidence.
₹15000.00 ₹20000.00 25% OFF
Course Overview
Radiology Physics & Imaging Technology
Foundations to Advanced Concepts for Diagnostic Excellence
Module Overview
Radiology Physics is the backbone of safe, high-quality imaging. This comprehensive module is designed to take radiology residents from first-principle physics to advanced modality-specific applications, ensuring conceptual clarity, exam readiness, and real-world clinical confidence.
This course integrates core physics concepts, imaging system design, image formation, dose optimization, artifacts, quality assurance, and emerging technologies like AI and photon-counting CT, making it ideal for PG entrance exams, DNB/MD training, and day-to-day reporting practice.
What You Will Gain from This Module
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Strong conceptual understanding of imaging physics
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Ability to predict image quality & artifacts
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Confident handling of radiation safety & regulations
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Clear understanding of technology behind each modality
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Exam-oriented preparation with clinical correlation
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Readiness for advanced imaging & future technologies
Schedule of Classes
Course Curriculum
16 Subjects
Basic Physics & Atomic Structure
Physical quantities & units
Atomic structure & nomenclature
Nuclear stability & binding energy
Isomeric transition
Radiation Fundamentals
Electromagnetic, particulate & acoustic radiation
Wavelength, frequency & EM spectrum
Isotopes & periodic table relevance
X-Ray Production & Detection
Properties of X-rays
Scintillation & semiconductor detectors
X-ray circuits, generators & production
X-Ray Tube & Beam Modification
X-ray tube design
Filters, collimators & grids
Interaction of Radiation with Matter
Photoelectric effect
Compton scattering
Pair production
Conventional & Digital Radiography
Film-screen radiography
Computed radiography
Digital radiography & printing
Fluoroscopy, DSA & Dental Imaging
Fluoroscopy, C-arm, OPG
DSA principles
Tomography & Cone Beam CT
Mammography & Breast Imaging
Conventional & digital mammography
Contrast mammography
Advanced breast imaging
CT Physics: Basics to Advanced
CT generations
Image acquisition & reconstruction
Dual energy, photon-counting, 4D CT
Ultrasound & Doppler Imaging
USG principles & transducers
Doppler imaging
Contrast USG & HIFU
MRI Physics
MRI instrumentation
Image acquisition
Sequences & advanced applications
MRI safety & artifacts
Nuclear Medicine & PET
Radioactivity & radiopharmaceuticals
Gamma camera & scintigraphy
PET agents, detectors & mechanisms
DEXA
Radiation Biology & Safety
Dosimetry & occupational hazards
Biological effects & radiation syndromes
Monitoring devices
Regulatory Framework & QA
AERB, ICRP, PCPNDT, NABH, E-LORA
Quality assurance & department planning
Artifacts & Image Optimization
Artifacts in X-ray, CT, USG, MRI, PET/SPECT
Post-processing techniques
Detector technologies
Contrast Media & AI in Radiology
IV, MRI & USG contrast media
Physical principles & applications
Artificial Intelligence in radiology
Course Instructor
Radnexa
17 Courses • 2 Students
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